Apparatus, Equipment and Method for Turf Treatment

ABSTRACT

An apparatus for treating turf, comprising: a cylindrical rotor, rotatable about an axis, the rotor having: a first helical track portion having a first helical track extending about the axis in a first direction from a first end towards a central portion thereof; a second helical track portion having a second helical track extending about the axis in a second direction between a second end and the central portion thereof; wherein each helical track portion comprises at least one helical track having a plurality of teeth arranged therealong.

RELATED APPLICATIONS

The present application the U.S. National Stage entry of International Application Number PCT/GB2018/051776 filed under the Patent Cooperation Treaty having a filing date of Jun. 26, 2018, which claims priority to GB Patent Application Number 1710318.5 having a filing date of Jun. 28, 2017, which are all herein incorporated by reference.

BACKGROUND

The present invention relates to an apparatus, equipment and method for turf treatment, and more particularly, but not exclusively, for treatment of sports playing surfaces such as football, rugby and hockey pitches, and tennis courts which, during the course of a playing season, are subject to wear and tear and also suffer from a build-up of ‘thatch’, which is an accumulation of layers of, for example, dead grass, partially decomposed leaves, stems and/or roots.

Diseases and other blights including algae, moss, fungi, and slime mould can invade the turf, and may be made worse by the presence of thatch. It is usually recommended that thatch be treated by mechanical thatching equipment, an operation usually referred to as scarification.

It is recommended to carry out scarification in several treatments rather than attempting to remove all the thatch at once, but this is essentially because conventional scarifiers remove thatch in thin furrows, leaving ‘ridges’ of thatch between them, and so cannot remove all the thatch in one pass.

U.S. Pat. No. 6,094,860 discloses the use of artificial fibre reinforcement for grass turf areas in playing fields subject to heavy wear, and other patents and proprietary systems such as “SISGrass®” and Desso® Grassmaster similarly involve the use of artificial fibre reinforcement.

Desso® Grassmaster is a turf reinforcement system in which artificial grass fibres are injected some 20 cm deep into a grass surface, projecting some 25 mm above the soil. The maintenance of this system, as regards mowing, verticutting and ventilating, is said to be no different from the maintenance of ordinary turf. Mowing, of course, must be carried out with the cutter height at or above the height of the artificial grass fibres, e.g. at 26 mm or more if the fibre height is 25 mm, otherwise the artificial grass fibres would be cut or pulled out.

The artificial grass fibres are injected into a matrix of sand, which of course has no nutritional value, and there is only a thin top layer of humus, if indeed any, so the natural grass needs to be treated with fertiliser more than it would if grown in deep soil. This exacerbates problems of disease and infestation, bearing in mind that about 97% of the turf is natural grass. The sand also, over the course of a playing season, compacts more than does the usual substrate of natural, non-reinforced turf.

Moreover, undesired grasses and weeds such as clover can be a problem on any turf. Clover is especially problematic on playing surfaces such as tennis courts, as it tends to be slippery. Weeds are usually treated with systemic herbicides, which take time to act and which may require several treatments over a space of weeks.

SUMMARY

The present invention provides an improved apparatus for treating turf, including artificial grass-reinforced turf planted in a matrix of, for example, sand and/or soil, that is capable of removing thatch, diseased or blighted humus and sand, even all of the grass and weeds, and without affecting artificial grass reinforcement, if present.

In a first aspect there is provided an apparatus for treating turf, comprising: a cylindrical rotor, rotatable about an axis, the rotor having: a first helical track portion having a first helical track extending about the axis in a first direction from a first end towards a central portion thereof; a second helical track portion having a second helical track extending about the axis in a second direction between a second end and the central portion thereof; wherein each helical track portion comprises at least one helical track having a plurality of teeth arranged therealong.

Such a configuration reduces the witness lines in comparison to rotors having helical track(s) extending in only one direction.

The first direction may comprise an anticlockwise direction, whilst the second direction comprises a clockwise direction.

Each helical track portion may comprise between one and ten equally spaced helical tracks, and preferably comprises four helical tracks.

The teeth may be individually attached to the respective helical tracks so as to be capable of individual removal for replacement or refurbishing or for reconfiguring the rotor.

The teeth may be bolted on to the helical tracks, and may be attached by a single bolt, the helical tracks having recesses or so arranged in relation to define a recess into which the teeth fit so as to be held securely in position by a single bolt.

The helical tracks may be welded to the surface of the rotor or fixed in slots, which may be laser-cut, in the rotor. The teeth may have tips extending at least 60 mm above the cylindrical surface of the rotor.

The tips may extend up to 200 mm above the cylindrical surface of the rotor. The teeth may be of wear resistant material or at least tipped with wear resistant material such as tungsten carbide at a tip portion thereof.

The teeth may extend on one or more helical tracks in each helical track portion, and there are, preferably four helical tracks per helical track portion.

With teeth closely spaced along each of the helical tracks, and set to an appropriate depth of penetration of the teeth, the rotor will be capable of removing in one pass all or substantially all thatch, grass and infected humus and/or sand.

In a second aspect there, is provided equipment for the treatment of turf, the equipment comprising the apparatus of the first aspect, the cylindrical rotor being traversed over the turf and rotated relative to the turf to lift material therefrom.

In a third aspect, there is provided a method for the treatment of turf comprising grass growing in a matrix, the method comprising: removing thatch or other infestation using the above apparatus of the first aspect.

BRIEF DESCRIPTION OF THE DRAWINGS

An apparatus, equipment and method according to the present invention will now be described with reference to the accompanying drawings, in which:

FIG. 1a is an illustrative example of a cross section of turf;

FIG. 1b is a cross section of turf similar to that of FIG. 1a reinforced with artificial grass fibres;

FIG. 1c is an illustrative example of a cross section of stoloniferous, warm season turf reinforced with artificial grass fibres;

FIG. 2 is a front view of one embodiment of an apparatus comprising a rotor;

FIG. 3 is a perspective view of the rotor of FIG. 2;

FIG. 4a is an enlarged perspective view of an end of the rotor of FIG. 2;

FIG. 4b is an end view of the rotor of FIG. 2;

FIG. 5 is a view of a single tooth for use in the apparatus of FIG. 2; and

FIG. 6 illustratively shows a rear view of an apparatus of FIG. 2 in use.

DETAILED DESCRIPTION

FIG. 1a is an illustrative example of a cross-section of turf 11 wherein natural grass 12 is, sown, for example, in sports surfaces such as tennis courts and football and rugby pitches, in a matrix 15 of, for example, soil, sand, silt and/or clay. The grass roots 12 a may be connected by rhizomes 12 b. Over time and as a result of mowing and wear, the turf acquires an accumulation thatch (not shown), and can also become infested with algae, moss, fungi, slime mould and other problems.

FIG. 1b is an illustrative example of a cross section of turf 11 a similar to that shown in FIG. 1 a, which is reinforced with artificial grass fibres 13 which extend a given height h above turf level 14, e.g. 25 mm. The natural grass 12 is usually sown in a matrix 15 a of, for example, sand with just a thin upper layer 16 of, for example, humus. Such reinforced turf can be more at risk of infestation through needing to be more heavily fertilised.

The artificial grass fibres 13 are injected a depth D, usually some 20 cm deep, through the humus 16 into the matrix 15 a.

FIG. 1c is an illustrative example of a cross section of stoloniferous, warm season turf 100, having an upper layer of turf 120 growing in a matrix 150 of, for example, soil and/or sand, comprising stalks 140 and blades 160 of warm season grass growing from crowns 170 and roots 180. Such warm season grass includes Bermudagrass and Buffalo grass.

The warm season grass also comprises stolons 190 which spread out from the crowns 170 so as to interconnect the crowns 170 above the top level of the matrix 150, whilst the rhizomes 195 spread out from the crowns 170 below the top level of the matrix 150.

In FIG. 1 c, the warm season turf is reinforced with artificial grass fibres 130 as described in FIG. 1b above. The warm season turf may be treated by removing the upper layer of turf 120 so as to remove material including the stalks 140, blades 160 and any thatch etc. which may build up in the upper layer 120, but not removing the stolons 190 or the artificial grass fibres 130. The warm season grass can then regenerate from the stolons 190.

An illustrative example of an infected layer is depicted in FIGS. 1a-1c by the respective brackets (B), whilst FIGS. 2-4 b illustrate an apparatus 10 for treating turf 11, 11 a, 100.

The apparatus 10 for treating turf and warm season turf comprises a cylindrical rotor 20 adapted to be driven in rotation about a horizontal axis, shown as axle 22, whereby two or more helical track portions 25 a/25 b on the rotor 20 each comprise one or more helical tracks 26 a/26 b.

The rotor 20 may be any length depending on the application, but is preferably between 0.5 m to 3 m in length, and preferably between 0.5 m and 2.5 m.

In the present illustrative example, the rotor 20 comprises two helical track portions 25 a & 25 b, whereby first helical track portion 25 a comprises four equally spaced helical tracks 26 a, extending from a first end 27 a of the rotor 20 towards a central portion of the rotor 20, whilst second helical track portion 25 b comprises four equally spaced helical tracks 26 b, extending from a second end 27 b of the rotor 20, towards a central portion of the rotor 20.

As illustratively shown in FIGS. 2 & 3, the helical tracks 26 a of the first helical track portion 25 a extend along the surface of the rotor 20 in an anticlockwise direction about the horizontal axis from the first end 27 a towards the central portion of the rotor 20, when viewed along the horizontal axis 22 from a first end 27 a towards a second end 27 b.

As illustratively shown in FIGS. 2-4 b, the helical tracks 26 b of the second helical track portion 25 b extend along the surface of the rotor 20 in a clockwise direction about the horizontal axis from the second end 27 b towards the central portion of the rotor 20, when viewed along the horizontal axis 22 from the second end 27 b towards the first end 27 a.

It will be appreciated that the term “central portion” is used for illustrative purposes only and the lengths of the first and second portions may be different from one another. For example, the first portion may be longer than the second portion or vice versa. In addition, the rotor 20 may comprise more than two helical track portions, each helical track portion of the rotor 20 having helical tracks extending in a direction different from the direction of the helical tracks of the adjacent helical track portions of the rotor 20. Each helical track comprises teeth 24 attached thereto, as described in greater detail below.

In alternative embodiments, different numbers of helical tracks may be provided in each of the different helical track portions (e.g. between 1 and 10 helical tracks per helical track portion).

Furthermore, the helical tracks 26 may extend in different directions from those of the present embodiment. In other embodiments the helical tracks in the first helical track portion may extend in a clockwise direction about the horizontal axis from the central portion towards the first end of the rotor, whilst the helical tracks in the second helical track portion may extend in an anticlockwise direction about the horizontal axis from the central portion towards the second end of the rotor.

In a further embodiment, the rotor comprises first and second helical track portions at first and second ends, with a third track portion having non-helical tracks provided therebetween. Such non-helical tracks may be arranged along the surface of the rotor substantially parallel to the axis.

In the present illustrative embodiments, the tracks 26 a, 26 b are depicted as a continuous stepped structure upstanding from the surface of the rotor 20.

However, the helical tracks 26 are not required to be continuous structures and, in other embodiments, may comprise a series of discrete brackets or posts to which the teeth 24 are attached. In other embodiments, the helical track 26 may comprise a slot(s) machined/etched into the surface of the rotor, into which the teeth 24 may be attached by insertment and being locked in place. In other examples, the teeth 24 may be permanently attached e.g. by welding.

It is advantageous that the teeth 24 are removably attached to the helical tracks 26, so that the teeth 24 may be replaced or refurbished when worn or damaged in use or so that the rotor 20 may be reconfigured for different operations (e.g. scarification).

FIG. 5 shows an illustrative example of a tooth 24, which is generally trapezoidal in shape. However, the claims are not limited in this respect, and any shape tooth may be used.

The tooth 24 comprises a body portion 24 formed of wear resistant material such as steel, and, in embodiments, comprises a steel tip portion 24 b comprising wear resistant material, such as tungsten carbide. The tip portion 24 b is arranged to be a height above the surface of the rotor 20 when attached to the track (e.g. from 10 mm up to 200 mm above the surface, and preferably, at least 60 mm above the surface).

The width of a tooth may be between 1 mm-30 mm, and preferably, the width of a tooth 24 is between 5-15 mm, and more preferably, the width of a tooth 24 is 10 mm.

For example, and as depicted in FIG. 4a which shows an enlarged view of the second end 27 b (as circled in FIG. 3), the teeth 24 may be bolted to the helical track 26 with a single bolt 25 through aperture 24 c, although any number of bolts may be used. Furthermore, the claims are not limited to bolting the teeth in place, and in other embodiments the teeth 24 may be fixed directly onto the rotor 20, or into slots in the rotor 20 surface.

In an example operation, with teeth 24 closely spaced along all helical tracks 26 to provide substantially full coverage across the rotor 20, the rotor 20 will be capable of removing in one pass all or substantially all thatch, grass and infected humus and or sand. It will be noted that the claims are not limited to the helical tracks terminating at the first end 27 a and/or second end 27 b of the rotor, but the helical tracks may terminate a distance therefrom e.g. up to 30 cm or more therefrom.

Referring to FIG. 6, the apparatus may, in use, be mounted in equipment comprising a chassis 42, and drawn over the turf 11 by a tractor 41 (the rotor is not shown in FIG. 6).

In the present illustrative example, the chassis 42 has a ground roller 43 and a height control arrangement 44 adapted to control the height of the rotor 20 relative to the turf so as to deploy the teeth 24 as required e.g. below turf level 14 or to skim the surface of the turf.

The tractor 41 is driven to traverse the rotor over the turf 11 in the direction 49 as also shown in FIGS. 4 b, which is an end view of the first end 27 a. The rotor is rotated in the direction 50 as shown in FIG. 4b as it traverses the turf in the direction of travel 49, so that the teeth 24 move through the turf 11 lifting material such as thatch, natural grass, blades, stalks and/or matrix material. Such rotation of the rotor in the direction 50 may be provided using a power take-off transmission 45 on the tractor 41.

The material lifted from the turf is pulled inwards from the respective ends 27 a/27 b by the action of the helically disposed teeth 24 and is transferred onto a conveyor belt 47 in the chassis 42 as the rotor 20 is rotated in the direction 50. When the helical tracks are formed as continuous structures as in FIGS. 2-4 b, any material falling from a particular tooth will be caught by the helical track to which it is attached before being transferred onto the conveyor belt from the helical track. Such functionality may also be provided when the helical tracks are not formed as continuous structures, whereby the teeth may be attached to each other such that no gaps exist therebetween, or whereby any posts or brackets may be provided with features to catch any material falling of the teeth. Without being limited to theory, the action of pulling the lifted material inwards may be seen as an Archimedean screw action due to the direction of the helically tracks.

The conveyor belt 47 carries the lifted material onto elevator 45 into a trailer 46 drawn behind a second tractor 48.

Pulling the material inwards from the respective ends 27 a/27 b before being lifted onto the conveyer belt 47 means that “witness lines” on the treated turf will be reduced, whereby a person skilled in the art will appreciate that witness lines comprise a visible line of remnant material that is not collected by the rotor.

As shown, the rotor height control arrangement is used to set the height of the rotor relative to the turf. The height control arrangement 44 is adjustable either continuously, or in fine steps (e.g. 1 mm or less, preferably 0.1 mm or less, and even further preferably 0.01 mm or less). For example, a geared arrangement with an input wheel effecting an adjustment of 0.1 mm per rotation allows for finer than 0.1 mm adjustment by a fractional turn. Such a degree of adjustability is highly advantageous, allowing for setting of the rotor height dependent on the requirements. A height control arrangement with a digital readout is also useful, and may be calibrated to indicate what the height of the rotor is. The skilled person will recognise that, for best performance, the height setting does not drift during use.

A typical rotational speed for such a rotor may be between 600-1400 rpm, and more preferably is approximately 1000 rpm, although the claims are not limited in this respect.

Thus equipment using a rotor of width >0.5 m may thus treat a football or like sized field on a single pass, or two passes at most, an operation comfortably accommodated within a single day's work.

With reference to FIGS. 1a and 1 b, treatment to a depth d at which at least some natural grass, roots, crowns, rhizomes, perhaps some culm, is left in the matrix 15/15 a will suffice, and the grass will grow back. However, when the matrix is badly infected with algae, all the natural grass may be removed by driving the teeth sufficiently deep, and new matrix laid down and reseeded.

Furthermore, when treating reinforced turf as in FIG. 1 b, the depth d is less than the depth of any mat or backing such as disclosed, for example, in U.S. Pat. Nos. 5,489,317 or 6,094,860.

Similarly, with the Desso Grassmaster® or SISGrass systems, which do not have a backing, the depth d should be less than the depth D to which the artificial fibres are injected, so that any artificial fibres will remain in place.

Furthermore still, when treating stoloniferous, warm season turf, as in FIG. 1 c, the depth d is such that the teeth skim the top surface of the matrix 150, and, preferably such that the teeth are above the stolons 190 in the upper is layer 120, such that the stolons 190, and any artificial fibres (if present) will remain in place after treatment.

The rotor 20 may be reconfigured by removing teeth from one or more of the helical tracks of the one or more helical potion 25 a or 25 b, so as to leave the rotor balanced—and deployed, using the height control, so that the teeth penetrate to a lesser depth, such that the rotor 20 functions as a scarifier.

While preferred embodiments of the invention have been described, it will be readily understood by those skilled in the art that variations may be made thereto without departing from the scope of the invention. For instance, and as described above, other configurations (e.g. numbers/directions) of helical track portions or helical tracks may be provided. 

1) An apparatus for treating turf, comprising: a cylindrical rotor, rotatable about an axis, the rotor having: a first helical track portion having a first helical track extending about the axis in a first direction from a first end towards a central portion thereof wherein the first direction comprises an anticlockwise direction; a second helical track portion having a second helical track extending about the axis in a second direction between a second end and the central portion thereof wherein the second direction comprises a clockwise direction; wherein each helical track portion comprises between 2 and 10 helical tracks having a plurality of teeth arranged therealong. 2) The apparatus according to claim 1, wherein each helical track portion comprises four helical tracks. 3) (canceled) 4) (canceled) 5) The apparatus according to claim 1, wherein each helical track comprises a substantially continuous structure upstanding from the surface of the rotor. 6) The apparatus according to claim 1, wherein each helical track comprises a series of discrete brackets or posts. 7) The apparatus according to claim 1, wherein each helical track comprises a slot in the surface of the rotor into which a tooth is inserted. 8) The apparatus according to claim 1, wherein the length of the first helical track portion is equal to the length of the second helical track portion. 9) The apparatus according to claim 1, wherein the length of the first helical track portion is not equal to the length of the second helical track portion. 10) Equipment for the treatment of turf, the equipment comprising a chassis and mounted therein the apparatus of claim 1, wherein the equipment is configured so that the cylindrical rotor traverses over the turf and rotates relative to the turf, so as to lift material therefrom. cm 11) Equipment according to claim 10, comprising a height control arrangement adapted to control the height of the rotor relative to the turf. 12) Equipment according to claim 10, the equipment comprising a conveyer belt to remove the lifted material therefrom. 13) A method for the treatment of turf comprising grass growing in a matrix, the method comprising: removing thatch or other infestation using an apparatus as claimed in claim
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